A Comparative Plasmonic Study of Nanoporous and Evaporated Gold Films

Previously, we have reported that nanoporous gold (NPG) films prepared by a chemical dealloying method have distinctive plasmonic properties, i.e., they can simultaneously support localized and propagating surface plasmon resonance modes (l-SPR and p-SPR, respectively). In this study, the plasmonic properties of NPG are quantified through direct comparison with thermally evaporated gold (EG) films. Cyclic voltammetry and electrochemical impedance spectroscopy experiments reveal that the NPG films have 4–8.5 times more accessible surface area than EG films. Assemblies of streptavidin–latex beads generate p-SPR responses on both NPG and EG films that correlate well with the bead density obtained from scanning electron microscopy (SEM) images. A layer-by-layer assembly experiment on NPG involving biotinylated anti-avidin IgG and avidin, studied by l-SPR and SEM, shows that the l-SPR signal is directly linked to the accessibility of the interior of the NPG porosity, an adjustable experimental parameter that can be set by the dealloying condition and time

Streptavidin binding to biotinylated lipid layers on solid supports. A neutron reflection and surface plasmon optical study.

Neutron reflection and surface plasmon optical experiments have been performed to evaluate structural data of the interfacial binding reaction between the protein streptavidin and a solid-supported lipid monolayer partly functionalized by biotin moieties. Since both experimental techniques operate in a total internal reflection geometry at a substrate/solution interface, identical sample architectures allow for a direct comparison between the results obtained with these two recently developed methods. It is found that a monomolecular layer of dipalmitoyllecithin doped with 5 mol% of a biotinylated-phosphatidylethanolamine shows a thickness of d1 approximately (3.4 +/- 0.5) nm. Binding of streptavidin to the biotin groups results in an overall layer thickness of d = (5.9 + 0.5) nm that demonstrates the formation of a well-ordered protein monolayer with the (biotin+spacer) units of the functionalized lipids being fully embedded into the binding pocket of the proteins. It is demonstrated by model calculations that a more detailed picture of the internal structure of this supramolecular assembly can only be obtained if one uses deuterated lipid molecules, thus generating a high contrast between individual layers

Translocation of Alkali Metal Cations by Lipophilic Cyclodextrin Derivatives through Black Lipid Membranes

AbstractLipophilic cyclodextrin (CD) derivatives, synthetic ionophores, were prepared to transport alkali metal cations across a black lipid membrane (BLM). The purpose of this study is to develop a new class of an artificial transportation system of alkali metal cations via bilayer lipid membranes, by using CD derivatives as a cation carrier. A lipophilic CD derivative incorporated into a BLM forms a complex with an alkali metal cation at one surface of the membrane. This charged complex migrates to the opposite side of the membrane and then releases the cation into the subphase. CD derivatives have various types of acyl groups as a complexing site and formed a 1:1 complex with the alkali metal cation. The complex formation was interpreted by an induced-fit mechanism. It is found that the ability of CD derivative for forming a complex and/or transporting cations across the BLM depends on the bulkiness of acyl groups. The conductivities of heptakis (2,6-di-O-propyl-3-O-propionyl)-β-CD were higher than those of valinomycin regardless of sizes of cations. The order of the conductivity in all derivatives is Li+<Na+<K+≈Rb+≈Cs+, regardless of the types of acyl groups in the derivatives. The effects of alkali metal cation concentration in the aqueous phase and CD concentration in the membrane on the translocation are also discussed